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Aalborg Universitet
Fluoroscopic Investigation of Cervical Joint Motion in Healthy Subjects
Wang, Xu
Publication date:2018
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Citation for published version (APA):Wang, X. (2018). Fluoroscopic Investigation of Cervical Joint Motion in Healthy Subjects. AalborgUniversitetsforlag. Aalborg Universitet. Det Sundhedsvidenskabelige Fakultet. Ph.D.-Serien
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FLuOrOSCOPIC INVESTIGaTION OFCErVICaL JOINT mOTION IN
HEaLTHy SuBJECTS
ByXu WaNG
Dissertation submitteD 2018
i
FLUOROSCOPIC INVESTIGATION OF
CERVICAL JOINT MOTION IN
HEALTHY SUBJECTS
PH.D. DISSERTATION
by
Xu Wang
Sensory and Motor Interaction, SMI®
Department of Health and Science Technology
Faculty of Medicine
Aalborg University
2018
Dissertation submitted: July 10, 2018
PhD supervisor: Prof. Thomas Graven-Nielsen, Aalborg University
Assistant PhD supervisor: René Lindstroem, Aalborg University
PhD committee: Associate Professor Mark de Zee, PhD (chairman) Aalborg University
Professor Jan Hartvigsen, Chiropractor, PhD University of Southern Denmark
Professor Alan Breen, DC, PhD Bournemouth University
PhD Series: Faculty of Medicine, Aalborg University
Department: Department of Health Science and Technology
ISSN (online): 2246-1302ISBN (online): 978-87-7210-231-3
Published by:Aalborg University PressLangagervej 2DK – 9220 Aalborg ØPhone: +45 [email protected]
© Copyright: Xu Wang
Printed in Denmark by Rosendahls, 2018
iii
TABLE OF CONTENTS
Table of contents ................................................................................................................ iii
Acknowledgements............................................................................................................... v
Preface .................................................................................................................................. vi
List of abbrevations ...........................................................................................................vii
1 Introduction .................................................................................................................. 1
1.1 Cervical spine anatomy ............................................................................. 2
1.2 Neck proprioception .................................................................................. 3
1.3 Aim of the PhD project ............................................................................. 3
1.4 Hypotheses ................................................................................................ 5
2 Methodology development ........................................................................................... 7
2.1. Facilities and equipments .......................................................................... 7
2.2. Novel methodology for image analysis ..................................................... 8
2.3. Joint motion analysis ............................................................................... 10
2.4. Reposition errors of cervical joint (Study I) ............................................ 11
2.5. Repeatability of cervical joint motion (Study II) ..................................... 12
2.6. Cervical joint anti-directional motion (Study III) .................................... 13
2.7. Statistical analysis ................................................................................... 14
3 Upright reposition error ............................................................................................ 15
3.1 Reposition error after cervical movement ............................................... 15
3.2 Cervical joint reposition errors ................................................................ 15
3.2.1 Real error ............................................................................................. 15
3.2.2 Absolute error ..................................................................................... 16
3.3 Time effects on reposition errors ............................................................. 17
3.4 Discussion ............................................................................................... 17
3.5 Summary ................................................................................................. 19
4 Dynamic cervical individual joint motion ................................................................ 20
4.1 Cervical joint motion repeatability .......................................................... 20
4.1.1 Within-day repeatebility ...................................................................... 20
4.1.2 Between-day repeatability ................................................................... 21
iv
4.1.3 Comparison of within and between day differences ........................... 21
4.2 Discussion ............................................................................................... 22
4.3 Clinical implications................................................................................ 23
4.4 Summary ................................................................................................. 23
5 Quantification of anti-directional motion ................................................................ 25
5.1 Anti-directional motion ........................................................................... 25
5.2 Joint motion during flexion and extension .............................................. 27
5.3 Discussion ............................................................................................... 30
5.4 Clinical Implications ............................................................................... 31
5.5 Summary ................................................................................................. 31
6 General discussion and limitations ........................................................................... 32
7 Future perspectives .................................................................................................... 37
8 Conclusion .................................................................................................................. 38
9 English summary ........................................................................................................ 39
10 Dansk sammenfatning ........................................................................................... 41
11 References .............................................................................................................. 43
12 Author’s CV ........................................................................................................... 52
v
ACKNOWLEDGEMENTS
The work presented in this Ph.D. thesis was carried out at the Center for
Neuroplasticity and Pain (CNAP), SMI, Faulty of Medicine, Department of Health
Science and Technology, Aalborg University during the period of Oct 2013 – Oct
2017 and was supported by Aalborg University, the China Scholarship Council (File
No. 201306170027) and S.C. Van Fonden (#1532). Completion of this thesis would
not have been possible without the guidance, help and support of the following
persons, to whom I would like to express my sincere gratitude:
To my supervisor Prof. Thomas Graven-Nielsen and co-supervisor René Lindstroem,
for giving me the chance to pursue a novel and interesting research topic. Thomas,
for his outstanding guidance, endless support and trust, and particularly, his constant
patience towards me throughout this work. René, for giving me endless
encouragement and inspiration, for sharing his infectious enthusiasm and knowledge
for research with me and for his patient guidance in writing scientific papers.
To the co-author of the scientific papers of this dissertation, Niels Peter Bak
Carstens, for providing the facilities and his technical and clinical assistance during
data collection. To the co-authors, Maciej Plocharski and Lasse Riis Østergaard, for
helping develop the Matlab-based program to analyze the cervical spine motions.
To Prof. Egon Toft, Doctor Haiying Yang, and Prof. Xiaoyu Yang for
recommending me to study at Aalborg University and especially Haiying for
providing great accommodation.
To the funds, S.C. Van Fonden, Oticon Fonden and Mønsteds Fond, for the financial
support to attend the 17th EFORT Congress conference.
Finally, to my English instructor Hanne Lisbeth, for her enthusiastic help on my
language and to my friends Jian Dong, Weiwei Xia, Jianhang Jiao, Ning Qu, Jiwei
Gu, Jie Zhang and colleagues Ann Karina Schelde, Susanne Nielsen Lundis, and
Lone Schødt Andersen and others at the Department of Health Science and
Technology for their excellent company.
The thesis is dedicated to my wife Miao and to my son Jackie for their endless
support throughout my Ph.D. life. Thank you for being with me every step of the
way – I could not have done it without you.
Xu Wang, Aalborg, September 2016
vi
PREFACE
The current Ph.D. thesis is based on three studies performed at the Center for
Sensory-Motor Interaction (SMI), Aalborg University, Denmark, from 2013 to 2018:
Study I: Wang X, Lindstoem R, Carstens N, Graven-Nielsen T (2017). Cervical
spine reposition errors after cervical flexion and extension. BMC Musculoskeletal
Disorders. 2017 Mar; 18(1): 182.
Study II: Wang X, Lindstroem R, Plocharski M, Østergaard L, Graven-Nielsen T
(2018). Repeatability of cervical joint flexion and extension within and between
days. J Manipulative Physiol Ther. 2018 Jan;41(1):10-18.
Study III: Wang X, Lindstroem R, Plocharski M, Østergaard L, Graven-Nielsen T
(2018). Cervical flexion and extension includes anti-directional cervical joint motion
in healthy adults. Spine J. 2018 Jan;18(1):147-154.
vii
LIST OF ABBREVATIONS
ROM Range of Motion
ICC Intra-class Correlation Coefficient
SEM Standard Error of Measurement
ANOVA Analysis of Variance
SD Standard Deviation
RM-ANOVA Repeated Measure-Analysis of Variance
F1 Upright posture before the flexion motion
F2 Upright posture after the flexion motion
E1 Upright posture before the extension motion
E2 Upright posture after the extension motion
1
1 INTRODUCTION
Neck pain is a common health problem and will be experienced by most people at
some point in their life (Daffner et al. 2003). The one-year prevalence rates range
from 4.8% to 79.5% (Hoy et al. 2010). Neck pain is an increasingly financial burden
for social health care systems. The costs of treating neck pain were estimated to be €
485 million in 1996 in the Netherlands (Driessen, Lin, and Tulder 2012). Neck pain
is associated with the impairment of muscles, ligaments and bony structures
(Gabriela F. Carvalho et al. 2014; Meisingset et al. 2016; Steilen et al. 2014;
Waseem et al. 2014).
Restricted cervical range of motion (ROM) was observed in patients with neck pain
(Hino et al. 1999; Houck, Yack, and Mulhausen 1997; Wibault et al. 2013). Cervical
ROM is described as a principle parameter of global neck function (Takeshima et al.
2002). The cervical ROM is most frequently measured between head and a lower
body parts, such as thoracic vertebrae or the sternal notch (Artz, Adams, and Dolan
2015; Wibault et al. 2013). However, the cervical ROM does not reveal
intervertebral cervical joint motion.
Cervical joint motion has been proposed to be more important and clinically relevant
for the understanding of cervical biomechanics and post-surgical assessments
compared to cervical ROM (Auerbach et al. 2011; Puglisi et al. 2007; Wu et al.
2010). However, dynamic cervical joint motion has not been investigated in depth,
and cervical joint motion patterns cannot be efficiently described from static images
as large variations of joint motion were found between static images (Anderst,
Donaldson et al. 2013a; Anderst, Donaldson et al. 2013b; Anderst et al. 2015).
Cervical ROM is highly correlated with neck problems and ROM is an important
parameter for diagnosis and rehabilitation of the cervical spine (Hino et al. 1999;
Houck et al. 1997). Patients with surgical fixation demonstrated smaller ROM in the
fused joint(s) and larger ROM in the adjacent joints (Auerbach et al. 2011). Surgical
fixations of cervical joints increased flexion and extension joint motion in the
adjacent joints with approximately 15% in comparison with healthy controls
(Anderst et al. 2013a). Studies of dynamic motion of cervical joint contribute to
diagnosis and treatment of neck pain; however, the knowledge of dynamic cervical
flexion and extension motion has not been investigated in depth.
Motor control is important for the assessment and treatment of patients with cervical
disorders (Patroncini et al. 2014). Deficient motor control is defined as impaired
controls of active movement compared to healthy subjects (Patroncini et al. 2014;
Woodhouse and Vasseljen 2008). Impaired cervical motor control is believed to
predispose patients to cervical lesions and/or pain (Patroncini et al. 2014).
Unfortunately, the knowledge of cervical motor control is weak. The repeatability of
2
cervical motions is assumed in clinical examination; however, the repeatability of
cervical joint motion has never been examined. A better understanding of
repeatability of healthy cervical joint motion is important for comparisons of joint
motions between and within day of healthy subjects and patients with neck pain
(Anderst et al. 2013a). Because the repeatability of cervical motion is essential for
diagnosis, rehabilitation and analysis of dynamic cervical spine motion.
Anti-directional, reversed or paradoxical joint motion (joint motion opposite the
intended motion direction) was previously demonstrated during flexion/extension
motion, and was observed in the two joints C0/C1 and C7/T1 (Anderst et al. 2015).
The C0/C1 anti-directional motion was demonstrated at the beginning and end of
cervical flexion, whereas the C7/T1 anti-directional motion occurs during the middle
of cervical flexion (Anderst et al. 2015). However, anti-directional motion has never
been quantified in cervical movements.
The cervical spine is commonly perceived with a motion strategy, where the deep
muscles support and stabilize a spring-like spine, while the superficial muscles
flexing or extending the neck (Bogduk 2016; Cramer 2014; Mathis 2006; Ombregt
2013). However, large variations in joint motions would indicate that the deep
muscles play a more active role in the cervical motor control. Anatomically, the
deep muscles provide precise motor control of movements of a single cervical joint,
in contrast to the superficial muscles, which are activated across multiple cervical
joints (Boyd-Clark, Briggs, and Galea 2002; O'Leary et al. 2009). The superficial
muscles cannot flex or extend one single joint alone, as the muscles traverse several
joints (Blouin et al. 2007; Siegmund et al. 2007). In contrast the deep muscles do
traverse single joints and can flex or extend a single joint.
Reinartz et al. reported different rates of change in cervical joint motion, including
changes in the motion direction (Reinartz et al. 2009). The motion patterns reported
by Reinartz et al. do not suggest a linear and continuous motion strategy of the
cervical joints. The motion pattern includes anti-directional motion of single joints
and suggests a more active motor control function of the deep cervical muscles
compared to the motion strategy without anti-directional motion (Ombregt 2013).
Nonlinear motor control may suggest variance or reposition error between cervical
joint motions. The upright head and neck posture is important for dynamic cervical
motion as most cervical motions are initiated from this position. The single joint
reposition errors between repeated upright positions after cervical motion have never
been examined and it is unknown if every single cervical joint demonstrates
reposition errors.
1.1 CERVICAL SPINE ANATOMY
The cervical spine consists of 7 vertebrae (C1- C7) and serves to orient the head and
to attach the head to the rest of the body. The atlas (C1) is a ring without a vertebral
3
body whose superior facets articulate with the occipital condyles (C0) and whose
inferior facets articulate with the axis (C2) (Bogduk, Amevo, and Pearcy 1995;
Devereaux 2007; Mathis 2006). The axis acts as the rotational axis for the head and
has an odontoid process and a prominent spire of bone thrusted cranially from the
axis vertebral body. Except for the first two vertebrae (atlas and axis), the other 5
cervical vertebrae share common morphologic features. Muscles and ligaments are
involved in stabilizing and controlling the movement of the cervical spine. The
multiple interconnections between two vertebrae will for simplicity be referred to as
a joint in this thesis. The cervical joints contribute to cervical range of motion, and
this thesis investigates cervical joint motion.
The sub-occipital anatomy and function are different when compared with the lower
cervical spine (Ombregt 2013). The distinguished osseous structure of the occiput,
atlas and axis underlie functional differences. Biomechanically, the cervical spine is
subdivided into three regions, the upper (C0-C1-C2), the middle (C2-C5) and the
lower (C5-T1) cervical spine (Panjabi and White 1980).
1.2 NECK PROPRIOCEPTION
Proprioception is essential for sensorimotor control of posture and movement
(Brooks 1983; Jong et al. 1977; Taylor and McCloskey 1988). Afferent
proprioceptive information is received from muscles, skin and joint receptors to
control the position and movement in space (Gandevia et al. 1992). Joint receptors
are believed to be activated near the end of motion, whereas muscle receptors are
postulated to be activated throughout the physical range of motion (Brumagne et al.
1999). Clinically, altered proprioception is believed to be associated with diseases of
joint and muscle, even though the clinical significance of this association remains
unclear. The understanding of proprioceptive impairment on cervical joint reposition
is important for diagnosis and rehabilitation of musculoskeletal problems (Allison
and Fukushima 2003).
1.3 AIM OF THE PHD PROJECT
This PhD thesis aims to investigate cervical joint motion during flexion and
extension in healthy subjects. The PhD thesis includes three studies of 1) the
reposition error of individual cervical joint; 2) repeatability of cervical joint motion
during flexion and extension; 3) anti-directional motion of cervical joint during
flexion and extension (Fig 1). The included studies investigate the dynamic joint
motion differences between two repeated cervical motions and characterize and
quantify the abundant anti-directional motions found in dynamic cervical joint
motion (Fig 1).
4
Figure 1. The PhD thesis consists of three studies of healthy subjects. The studies
investigate the static reposition error of cervical joints, cervical joint motion
repeatability and anti-directional cervical joint motion.
Quantity of anti-directional motion
Study III Joint motion repeatability
Study II Static reposition error
Study I
Joint motion characteristics
Repositioning/Repeatability/Anti-directional motion
5
1.4 HYPOTHESES
Individual joint motion has provoked greater interest in order to detect potential
clinical associations with diagnosis and rehabilitation (Anderst et al. 2013a; Branney
and Breen 2014; Bogduk et al. 1995; Dvorak et al. 1988). Normative data for
healthy cervical joint motion is a prerequisite for detection of such associations. The
purpose of this PhD project was to investigate dynamic cervical joint motion for
repeatability and reposition of the cervical spine. Three hypotheses were tested in
three studies, with the main hypothesis that cervical joint motions are repeatable:
1. (Study I)
All cervical joints return to the upright posture after end-range cervical flexion
and extension movements with uneven (unevenly distributed) reposition errors
influenced by time delay.
2. (Study II)
Cervical flexion and extension joint motion initiated from the upright posture is
repeatable throughout the motion with uneven (unevenly distributed)
repeatability differences influenced by time delay.
3. (Study III)
Cervical joints demonstrate anti-directional motion during cervical flexion and
extension motion.
7
2 METHODOLOGY DEVELOPMENT
2.1. FACILITIES AND EQUIPMENTS
Static end-range X-rays are often used to assess neck function. However, static X-
rays fail to show the dynamic joint motion of individual joints. To address this
problem, video fluoroscopy was developed for the analysis of dynamic cervical joint
motion (Branney and Breen 2014; Reinartz et al. 2009; Wu et al. 2010).
Dynamic cervical movement was captured with video fluoroscopy and analyzed
with the assistance of a Matlab-based program. The developed methods have high
reliability and validity (Ahmadi et al. 2009; Croft et al. 1994; Muggleton and Allen
1997; Okawa et al. 1998; Wu et al. 2010).
Wu et al. assessed the cervical joint motion from C2 to C7 (Wu et al. 2010).
Branney et al. assessed cervical joint motion from C1 to C6 (Branney and Breen
2014). Most of the previous studies have only investigated the middle and lower
cervical joints (Anderst et al. 2013a; Anderst et al. 2013b; Wu et al. 2010). The
unique anatomical shapes and complex imaging of the upper cervical joints are the
explanation for the problems in analyzing these joints (Anderst et al. 2013a; Anderst
et al. 2013b; Wu et al. 2010).
A pivot arm has been used to control cervical movements (Branney and Breen 2014).
The pivot gives a better control of the movement range and speed, while sacrificing
some of the freedom of the strategies of cervical motor controls. Most studies have
investigated free and unrestricted cervical movements. Anderst et al. did this from
end-range of flexion to end-range of extension in one continuous motion (Anderst et
al. 2013a; Anderst et al. 2013b; Anderst et al. 2015). Wu et al. used a different
method. They investigated free and unrestricted cervical movements from the
upright position to end-range of flexion or extension (Wu et al. 2007; Wu et al.
2010).
Joint motion was previously assessed from selected video images of flexion and
extension movements. Dynamic cervical flexion and extension motions have
previously been divided into intervals or epochs for extraction of the joint motion
(Anderst et al. 2013a; Anderst et al. 2013b; Anderst et al. 2015; Reinartz et al. 2009;
Wu et al. 2007; Wu et al. 2010). Wu et al. investigated the cervical dynamic motion
by dividing cervical motion into three intervals (Wu et al. 2010). Wu s method may
have been flawed, as the motion was extracted in absolute values, and absolute
values reflect the magnitude of the motion but neglect the direction of the motion.
Wu et al. also divided flexion and extension motion into ten intervals (Wu et al.
2007). Dynamic joint motions have been assessed with automated analysis, which
8
allowed analysis of all images in a video (Anderst et al. 2013b; Branney and Breen
2014; Reinartz et al. 2009).
Most analysis methods are developed from the work of Frobin et al. (Frobin et al.
2002). Frobin et al. marked squared vertebral bodies in each of their corners, and the
diverse anatomy of the upper cervical regions were marked with 2 points (Frobin et
al. 2002) (Fig 2).
2.2. NOVEL METHODOLOGY FOR IMAGE ANALYSIS
Novel features improved the fluoroscopy and analysis method of dynamic joint
motion. The most important improvement in the present work was the addition of
external markers to identify C0. The external markers were four metal balls on
pliable wires attached to a pair of glasses worn by the participants. These new
markers were highly accurate compared to the previously applied skin markers, as
the skin of ear and nose do move during cervical movements (Wu et al. 2007).
The new markers allow for calculation of cervical ROM for the entire neck with the
head included, and this again allows for comparison of results with previous non-
fluoroscopic ROM studies. The movement below C7 was controlled by straps as the
movement below C7 may influence the cervical ROM (Auerbach et al. 2011).
Frobin’s methods were further developed to identify upper cervical anatomy and
several improvements were made to increase the accuracy of the manual marking
system including the external markers for C0, improved corner marking procedures,
improved marking of C1, protocols for enlargement of images during marking and
change of the gray scale of the images (Fig 2). The Matlab-based program was
written to calculate mid-planes from the marking points of each vertebrae.
The mid-plane of vertebrae with two marking points went through the anterior and
posterior points. While the mid-plane of vertebrae with four marking points went
through the midpoint of the two anterior points and midpoint of the two posterior
points. Cervical joint angle was calculated as the angle between the mid-planes of
two adjacent vertebrae (Fig 2).
9
Figure 2. The analysis included 26 marking points. External markers for C0 were 4
metal balls attached on pliable wires on a pair of glasses. Two points for C1 were
the central areas of the medullary cavities of the anterior and posterior arch. Two
points for C2 were the inferior vertebral plate. Four points for C3- C6 were in
proximity to the ends of the vertebral plates. Imaging of the lower part of C7
vertebrae was often obscured by the shoulder shadow and this vertebra was only
marked with two points at the end of the superior vertebral plate.
The manual marking of images was time-consuming, and the marking error was the
largest confounder; however, the marking error was indicated to be reliable as
reflected by high ICCs (larger than 0.90) (Wang et al. 2017a). Nevertheless, it is
possible that some of the variance found in the studies may originate from marking
errors.
10
2.3. JOINT MOTION ANALYSIS
This thesis investigates cervical joint motions between C0 to C7. Fluoroscopic
videos were applied to track the cervical movement from the neutral position to the
end-range positions. The videos were evenly divided into 10 epochs with respect to
the cervical C0/C7 ROM. When an image was not found at the exact 10% C0/C7
position, two images on either side of the 10% C0/C7 epoch were selected, marked
and interpolated to obtain the exact 10% C0/C7 position. Therefore, nine
interpolated position images, one neutral position image, and one end-range position
image were selected and marked for analysis of cervical flexion or extension joint
motion from C0/C1 to C6/C7 (Fig 3). Joint motion in each 10th epoch was computed
as the difference between two adjacent 10% images. Thus, one flexion or extension
video yielded seventy joint motion angles. Cervical C0/C7 ROM was the sum of the
70 joint motion angles.
11
Figure 3. The joint motion analysis process from fluoroscopic video to motion in
degrees. Boxes on the left side show the joint motion analysis in more details.
2.4. REPOSITION ERRORS OF CERVICAL JOINT (STUDY I)
Static reposition errors in the upright posture of all single cervical joints were
assessed after flexion and extension movements in four tasks. The four tasks were
explained in Figure 4 and named ‘Flexion’, ‘Extension’, ‘Setup adaptation’ and
‘Complete sessions’. The four repeated tasks were completed in different time
12
deviations with 20 seconds for ‘Flexion’ and ‘Extension’, 300 s for ‘Setup
adaptation’ and 340 s for ‘Complete sessions’. The reposition error was the
difference in degrees between two upright joint positions. The reposition error was
calculated between the start positions of the neck motions. The reposition error was
calculated as real errors in real values and as absolute errors in absolute values.
Figure 4. The experimental procedures of study I. The first row shows the time
between each motion or of the setup adjustment. An adjustment of the setup was
necessary between recordings of flexion and extension videos. The second row
shows the motions of flexion (Flex), extension (Ext) and the return motions to
upright after flexion or extension (Return), these motions are illustrated in the third
row. The flexion and extension motions were recorded while the return motion was
not recorded in order to reduce radiation exposure. The fourth row shows the four
upright positions which were entered in the analysis of joint reposition errors. F1:
the upright position before the first flexion F2: the upright position before the
second or repeated flexion E1: the upright position before the first extension E2: the
upright position before the second or repeated extension. The reposition errors for
‘Extension’ and ‘Flexion’ were calculated between two upright positions (F1, F2)
and two upright positions (E1 and E2), respectively. The reposition error between
F1 and F2 was called ‘Flexion’, and the reposition error between E1 and E2 was
called ‘Extension’. ‘Setup adaptation’ was the reposition error between F2 and E1
(300s). ‘Complete sessions’ was the reposition error between F1 and E2 (340s).
2.5. REPEATABILITY OF CERVICAL JOINT MOTION (STUDY II)
Dynamic joint motion repeatability was investigated in repeated flexions or
extensions. The experiments in Study II were conducted in two parts. The first part
examined within-day repetitions of cervical flexion and extension motions with 20 s
13
between repetitions (Fig 5). The second part examined between-day repetitions with
1 week between repetitions (Fig 5).
Figure 5. The experimental procedures of study II. The first row shows the flexion
(Flex) or extension (Ext), Interval (time internal between first and second or
repeated motion), Repeat (second or repeated flexion or extension motion). The
second row illustrates the 20 second within day time intervals between two repeated
flexions or extensions. The third row illustrates the 1 week between day time
intervals.
The dynamic joint motion was calculated as joint motion angles for 7 joints and in
10 epochs for each joint. Repeatability differences were extracted by subtraction of
joint motion angles in corresponding epochs between two repeated flexions or
extensions. Each repeated within-day or between-day flexion or extension yielded 7
X 10 joint motion angle differences. Likewise, the absolute values of the joint
motion angle differences were extracted.
2.6. CERVICAL JOINT ANTI-DIRECTIONAL MOTION (STUDY III)
Anti-directional joint motion was defined as the opposite motion to the intended
motion direction (pro-directional). Joint motion was calculated as the difference in
degrees between two adjacent interpolated images. Each flexion or extension yielded
70 joint motion angles (10 joint motion angles for each joint from C0/C1 to C6/C7).
Two repeated flexion or two repeated extension movements were analyzed and
averaged to 70 joint motion angles before computing the anti- and pro-directional
joint motions (Fig 6).
14
Figure 6. The experimental procedures in study III. The first row shows the recorded
flexion (Flex) and extension (Ext) and the not recorded return motions (Return). The
first row also shows a box, which indicates time used to change the setup between
flexion and extensions recordings. The second row shows the motion orders. This
experiment includes two recorded repetitions of flexion and extension from neutral
to end-range position. The return motion to the upright position was not recorded as
precautionary measure to reduce radiation exposure.
The pro-directional or anti-directional joint motion was extracted from each epoch
as positive or negative number in degrees, respectively. The actual range of motion
of C0/C7 was the sum of all the 70 joint motion angles. For extension the pro-
directional C0/C7 motion was the sum of the positive numbers among the 70 joint
motion angles, while the sum of the negative numbers was the anti-directional
C0/C7 motion, and vice versa for flexion. Joint specific pro- or anti-directional
motion across all epochs were extracted and summed for joints. The ratio between
anti-directional and pro-directional motions was calculated in percent (0% = no anti-
directional movement).
2.7. STATISTICAL ANALYSIS
Data distribution was tested with Shapiro-Will test and Q-Q plot. For each single
joint real errors or absolute errors in the four tasks (‘Flexion’, ‘Extension’, ‘Setup
adaptation’ and ‘Complete session’) were compared using the Friedman test
followed by post hoc Wilcoxon test if significant. Kruskal-Wallis test was applied to
detect the difference between joints in each task. Two-way repeated measure
analysis of variance (RM-ANOVA) were performed to compare the joint motion
angles for the first and second repetitions with within-subject factors as epoch (10)
and repetition (1st, 2nd). Post hoc test Tukey was used for pair-wise comparisons
when significant. The joint motion angle differences and the absolute joint motion
angle differences over time for flexion or extension were compared with a mixed
model ANOVA with epochs as within-subject factor and time (20s interval, 1-week
interval) and joint (C0/C1 to C6/C7) as between-subject factors. The ratios between
anti- and pro-directional motion were compared by a mixed model ANOVA with
joint (7 cervical joints) as between-participant factor and movement (flexion and
extension) as within-participant factor. Post hoc analysis Tukey’s test was followed
for pairwise comparisons. Significance level was set at P<0.05. Statistical analysis
was performed in SPSS (version 22, IBM, New York, US).
15
3 UPRIGHT REPOSITION ERROR
3.1 REPOSITION ERROR AFTER CERVICAL MOVEMENT
The human upright head and neck posture is abundant in our daily life, and the
upright posture of the neck is probably the most common neck posture. Clinically,
the upright head and neck posture is the baseline position for cervical spine
examinations such as cervical ROM and radiographic examination of the cervical
spine. Thus, the upright neck posture and the variation of the upright neck posture
are integrated in the daily life of healthy subjects, as well as the evaluation of trauma
and disease in patients with neck pain. In research, the upright head and neck
posture served as the baseline for assessment of cervical spine motion or head and
neck proprioception (Armstrong, McNair, and Williams 2005; Pinsault and
Vuillerme 2010; Reid et al. 2014; Treleaven, Jull, and Sterling 2003; Wibault et al.
2013). Reposition error was an important outcome in proprioception studies, while
individual cervical joint position sense and reposition error have received little
attention, because it was assumed that the upright neck posture was stable and
always reestablished with reposition errors of no consequences.
The repositioning error of the cervical spine has been measured by different methods,
including the 3Space Fastrak device, Cervical Range of Motion (CROM), and the
ultrasound-based motion analysis system (Armstrong et al. 2005; Treleaven et al.
2003; Wibault et al. 2013). All the methods were validated with good reliability
(Lee et al. 2006; Pearcy and Hindle 1989; Wibault et al. 2013). Most of these
studies measured head repositioning acuity with respect to a lower body part, for
instance the sternal notch (Artz et al. 2015). This method assessed the neck as one
unit and without stating that repositioning errors of the head and neck are composed
of reposition errors from multiple individual cervical joints.
3.2 CERVICAL JOINT REPOSITION ERRORS
3.2.1 REAL ERROR
The real reposition error of the cervical joints indicated that the cervical spine can
return to the upright posture after flexion and extension movements with average
variations of 0.21 degrees for flexion and 0.01 degrees for extension in Table 1
(Study I).
Study I showed that the average upright head reposition error in healthy subjects
approaches zero in Table 1. The study also showed that single joint could have large
reposition errors. These large reposition errors were often counterbalanced by large
reposition errors in other joints to maintain a suitable head posture.
16
Table 1. Mean (± SEM) reposition errors in single joints and the average of all the
single joints in degrees from tasks (‘flexion’, ‘extension’, ‘setup adaptation’ and
‘complete session’). The ‘task time’ indicates the time cost of each task.
Significantly different from C2/C3 compared to the other joints in the ‘setup
adaptation’ task. (*, P<0.05). Partly reused from Study I with permission (Wang et
al. 2017).
3.2.2 ABSOLUTE ERROR
The absolute reposition errors showed that the cervical spine returns to the upright
posture with an average error of 2.36 degrees for flexion and 2.50 degrees for
extension in Table 2 (Study I). In addition, visual inspection of Table 2 showed that
the upper cervical joints (C0/C1, C1/C2) showed larger errors compared with that of
the other cervical joints, especially for ‘Setup adaptations’ and ‘Complete sessions’
(Wang et al. 2017).
Table 1. Real reposition errors of cervical joint
Joints Flexion Extension Setup
adaptation
Complete
Session
Task time 20 s 20 s 300 s 340 s
Average 0.21 ± 0.28 0.01 ± 0.30 0.12 ± 0.45 0.34 ± 0.44
C0/C1 1.74 ± 0.88 1.74 ± 0.68 -4.82 ± 1.98* -1.35 ± 2.01
C1/C2 0.05 ± 0.79 -0.66 ± 1.20 1.66 ± 1.09 1.06 ± 1.33
C2/C3 -0.70 ± 0.71 -0.52 ± 0.60 1.96 ± 0.67 0.74 ± 0.71
C3/C4 -0.63 ± 0.58 -0.65 ± 0.69 0.25 ± 0.81 0.27 ± 0.54
C4/C5 1.49 ± 0.61 -0.37 ± 0.66 -0.32 ± 0.69 0.80 ± 0.80
C5/C6 -0.31 ± 0.67 0.27 ± 0.79 0.42 ± 0.76 0.38 ± 0.85
C6/C7 -0.29 ± 0.78 -1.14 ± 0.81 1.89 ± 0.98 0.46 ± 1.37
Table 2. Absolute reposition errors of cervical joint
Joints Flexion Extension Setup
adaptation
Complete
Session
Task time 20 s 20 s 300 s 340 s
Average 2.36 ± 0.19* 2.50 ± 0.22* 3.31 ± 0.35 3.45 ± 0.33
C0/C1 2.36 ± 0.67 2.34 ± 0.59 5.98 ± 1.80 6.13 ± 1.47
C1/C2 2.50 ± 0.54 2.92 ± 1.00 3.67 ± 0.80 4.06 ± 0.98
C2/C3 2.14 ± 0.54 2.13 ± 0.37 2.60 ± 0.54 2.21 ± 0.52
C3/C4 1.98 ± 0.38 2.49 ± 0.42 2.56 ± 0.57 1.75 ± 0.37
C4/C5 2.19 ± 0.48 2.28 ± 0.41 2.57 ± 0.37 2.94 ± 0.47
C5/C6 2.32 ± 0.37 2.45 ± 0.53 2.37 ± 0.51 2.75 ± 0.53
C6/C7 2.32 ± 0.55 3.01 ± 0.45* 3.29 ± 0.73 4.35 ± 0.89
17
Table 2. Mean (± SEM) reposition errors of single joints and the average of the
single joints in degrees across ‘flexion’, ‘extension’, ‘setup adaptation’ and
‘complete session’. The ‘Task time’ shows the time cost of each task. The reposition
errors in ‘Flexion’ and ‘Extension’ were different compared with ‘complete session’
by Friedman test (*, P<0.05). Partly reused from Study I with permission (Wang et
al. 2017).
3.3 TIME EFFECTS ON REPOSITION ERRORS
The real errors demonstrated no time effects.
Reposition errors from longer time intervals (340s) were larger compared to
reposition errors from shorter time intervals (20s) (Study I). This time effect on
cervical joint repositioning errors was found in absolute errors but not in real errors
in Table 1 & 2. The study showed conflicting results which indicate that increased
absolute errors in the 340 seconds task (‘Complete sessions’) compared to the 20
seconds tasks (’Flexion’ and ‘Extension’). However, a similar result was not shown
for comparisons with the 300 seconds task (’Setup adaptation’) in Table 2 (Study I).
3.4 DISCUSSION
The results supported the hypothesis that all single cervical joints showed uneven
reposition errors after cervical flexion and extension movements. However, the
cervical spine can return to the upright posture within a small average variation of
0.21° and 0.01° for real errors of flexion and extension and 2.36° and 2.50° for
absolute errors of flexion and extension.
The results showed conflicting evidence for the hypothesis that time influences the
repositioning ability of cervical joints, as the results demonstrated conflicting
evidence on the effect of time on reposition errors of cervical joints.
The upper cervical joints demonstrated a larger amount of repositioning errors
compared with that of the lower joints. This difference may be due to the different
anatomy of the upper and lower cervical vertebrae.
Proprioception initiated from muscle spindles is an essential element in motor
control and repositioning (Artz et al. 2015; Newcomer et al. 2000; O'Sullivan et al.
2003; Wang et al. 2017). Healthy controls demonstrated larger repositioning errors
in the upper cervical joints compared with the lower ones (Study I). Anatomically,
the upper cervical spine consists of more muscle spindles compared to the lower
cervical region (Kulkarni, Chandy, and Babu 2001). In contrast, larger repositioning
errors were shown in the upper cervical joints, which are in contrast with the larger
amount of muscle spindles.
18
Treleaven et al. have also demonstrated larger reposition errors in the upper cervical
region in neck pain patients (Treleaven et al. 2011). Thus, the upper cervical region
demonstrated less repositioning acuity in both healthy controls and neck pain
patients. Treleaven et al. suggested the repositioning errors in the upper and lower
cervical regions should not be grouped, as grouping may reduce homogeneity. The
larger repositioning errors in the upper cervical region were in line with the
suggestion that the cervical spine should not be considered as a single unit, and that
the cervical spine should be treated as a complex structure with multiple units of
motion.
The real errors indicated that the cervical spine can return to the upright head and
neck posture with only a minor error of on average 0.21 and 0.01 degrees. The small
real reposition error is in line with the previous assumptions that the upright head
and neck posture can return in healthy subjects. However, the absolute values in
Study I showed that the cervical spine returns to the upright posture with an average
absolute error of 2.36 and 2.50 degrees. Similarly, Artz et al. reported reposition
errors after flexion and extension ranging from 1.61 to 2.25 degrees but considered
the cervical spine as a single unit (Artz et al. 2015). The cervical spine was able to
maintain the natural head and neck posture by compensating for large variation in
other joints. The large variation in both real errors and absolute errors indicate that
the results should be applied to the individual subject level with caution, and that
cervical reposition error may not be suited for diagnosis.
The accuracy of upright cervical joint position sense in healthy controls is important,
as the reposition errors may be reflected in dynamic cervical flexion and extension
movements and in clinical conditions. The upright head and neck position is the
position from which most movements begin (Walmsley, Kimber, and Culham 1996).
The cervical joints can return to the initial position after flexion and extension
movements with a variation of approximately 2.36 and 2.50 degrees (Study I). This
raises the question as to whether the variation of the upright neck and head posture
influences the cervical joint motion pattern throughout the entire flexion or
extension movements.
Uneven distribution of the real errors suggested that the cervical spine
counterbalanced flexion and extension movements with a resultant average error
approaching zero. The counterbalance appears across multiple joints and serves to
orient the head in a suitable position after flexion and extension.
No significant time effects were detected for real errors. The results were
inconclusive for effect of time on absolute errors. Increased errors were found for
longer time (340 s) compared with shorter time (20 s); however, this result was not
demonstrated for 300 seconds when compared with 20 seconds. The results showed
conflicting evidence on the effects of time on reposition errors, thus it is difficult to
conclude that the reposition ability of the upright cervical spine position decreases
19
with time, although the magnitude of the error was larger as time increased.
Therefore, it is necessary to conduct further studies to test the effect of time on joint
position sense.
3.5 SUMMARY
Study I demonstrated that the position sense of all the cervical joints varies after
flexion and extension movements and it has been influenced by time. The study may
provide normal variation data for cervical spine upright position, which could be
compared with patient for diagnostic purposes. This is the first investigation of
single cervical joint repositioning errors. The study demonstrated in absolute values
a variation of upright position of approximately 2.36 and 2.50 degrees for flexion
and extension, respectively.
20
4 DYNAMIC CERVICAL INDIVIDUAL JOINT MOTION
The common clinical and scientific perception is that cervical joints move in
curvilinear patterns and repeat their motions. However, new evidence shows that
cervical joints move in convoluted patterns, with multiple changes of motion
direction (Anderst et al. 2013a; Anderst et al. 2013; Wu et al. 2010). The new
knowledge of cervical joint motion raises the question: Are dynamic cervical joint
motion patterns repeated?
4.1 CERVICAL JOINT MOTION REPEATABILITY
The upright head and neck posture is the initial start position for cervical motions
such as flexion, extension, axial rotation and lateral bending. Study I demonstrated
that the cervical spine returns after full flexion and extension motions with an
average variation of 2.36 degrees for flexion and 2.50 degrees for extension.
The repeatability of dynamic cervical joint motion is important for the
understanding of cervical biomechanics. The question of repeatability is also of
clinical importance as repeated examinations of cervical joint motion are used in
spinal diagnosis and in assessment of treatment (Borghouts et al. 1999; Cleland et
al. 2006; Fjellner et al. 1999; Strender, Lundin, and Nell 1997; Viikari-Juntura
1987). The motion pattern of the cervical spine has been assumed repeatable in
clinical motion palpation examinations and other clinical examinations (Letícia et al.
2016; Overmeer et al. 2016; Pho and Godges 2004; Rebbeck et al. 2016). However,
the assumed cervical motion repeatability has never been verified. In this thesis,
cervical joint motion repeatability was investigated with a 20 s time difference
(within-day repeatability) and a 1-week time difference (between-day repeatability).
Free and unrestricted cervical flexion and extension movements were repeated in
Study II. The movements started and were repeated from the upright posture. Free
and unrestricted cervical motion was chosen to mimic real-life motions. However,
this was standardized with firm fixation of the upper thoracic spine, as upper
thoracic motion is reported to influence the cervical spine motion (Edmondston et al.
2011; Katzman, Vittinghoff, and Kado 2011; Lau et al. 2010).
4.1.1 WITHIN-DAY REPEATEBILITY
Comparisons of joint motion angles of cervical flexion and extension motions
showed no significant differences in RM-ANOVA when repeated with 20s.
21
However, main effects of epochs for C1/C2 and C6/C7 were found in flexion. No
further interaction effects were detected. For C1/C2, larger joint motion angles were
shown for 10th epoch of flexion compared to 2nd and 7th epochs (Post hoc analysis,
Tukey: P<0.04). For C6/C7, smaller joint motion angles were found between the 9th
and 10th epochs of flexion compared to 2nd, 4th and 5th epochs of flexion (Post hoc
analysis, Tukey: P<0.04) (Study II).
4.1.2 BETWEEN-DAY REPEATABILITY
Between-day cervical joint motion showed no significant differences for individual
joints of flexion and extension motions. Significant main effects were found for
epochs of C6/C7 during flexion, with smaller motions in the 10th epoch of flexion
compared with the 1st, 2nd and 7th epochs (Post hoc analysis, Tukey: P<0.04) (Study
II).
4.1.3 COMPARISON OF WITHIN AND BETWEEN DAY DIFFERENCES
The average within-day difference across all joints and epochs were 0.00° (SD 2.98°)
and 0.00° (SD 3.05°) for flexion and extension, respectively. Likewise, the average
between-day differences were 0.01° (SD 2.56°) and 0.05° (SD 2.40°) for flexion and
extension, respectively (Study II). The within-day and between-day joint motion
angle differences for each joint were presented in Table 3. In addition, the absolute
within-day and between-day joint motion angle differences were presented in Table
4. No significant differences were found between measures of within-day and
between-day repeatability for real or absolute joint motion angles (Study II). The
results indicated that the repeatability of cervical joint motion was not influenced by
time (20s vs 1 week).
Table 3. Within-day and between-day joint motion angle differences
Joint Within-day Between-day
Flexion Extension Flexion Extension
C0/C1 -0.03° (2.95°) 0.01° (2.68°) 0.05° (1.76°) 0.19° (1.87°)
C1/C2 -0.15° (3.79°) -0.16° (3.79°) -0.12° (2.98°) 0.08° (2.61°)
C2/C3 0.01° (3.18°) 0.05° (3.81°) 0.08° (3.40°) -0.01° (2.78°)
C3/C4 0.08° (2.59°) 0.04° (2.76°) 0.03° (2.52°) 0.08° (2.09°)
C4/C5 0.05° (2.93°) 0.08° (2.95°) -0.13° (2.20°) -0.02° (2.55°)
C5/C6 0.04° (2.53°) -0.05° (2.65°) 0.09° (2.38°) 0.01° (2.45°)
C6/C7 0.00° (2.93°) -0.01° (2.42°) 0.10° (2.38°) 0.03° (2.35°)
Average 0.00° (2.98°) 0.00° (3.05°) 0.01° (2.56°) 0.05° (2.40°)
22
Table 3. The Mean (SD) in degrees of within-day and between-day joint motion
angle differences of repeated flexion and extension movements. ’Average’ indicates
the joint motion angle differences across all the joints. The joint motion angle
differences for flexion were presented in column 2 and 4 and extension were in
column 3 and 5, respectively. Reused from Study II with permission (Wang et al.
2018a)
Table4. The Mean (SD) in degrees of within-day and between-day absolute joint
motion angle differences of repeated flexion and extension movements. ’Average’
indicates the absolute joint motion angle differences across all the joints. The
absolute joint motion angle differences for flexion were presented in column 2 and 4
and extension were in column 3 and 5, respectively.
4.2 DISCUSSION
Study II showed that cervical joints could repeat their full flexion and extension
movements without influence of time delays. The hypothesis was confirmed on
group level with average difference between repetitions from 0.00 to 0.05 degrees.
The hypothesis was also confirmed on participant level with some limitation as the
SD of the repetitions ranged from 1.76 to 3.81 degrees. The absolute repeatability
differences for the cervical joints ranged between 2.02 and 2.33 degrees with the SD
ranging from 1.32 to 4.02 degrees.
Interestingly, the results showed no effect of time on repeatability of cervical
motions (20s vs 1 week). This result could indicate that cervical motor control was
independent of time. However, further studies are needed to confirm the
repeatability of cervical joint motions after longer time interval, as most of the
Table 4. Within-day and between-day absolute joint motion angle differences
Joint Within-day Between-day
Flexion Extension Flexion Extension
C0/C1 2.98° (4.02°) 2.71° (2.62°) 3.76° (2.92°) 2.43° (2.50°)
C1/C2 2.43° (2.37°) 2.53° (2.25°) 2.44° (2.92°) 2.71° (3.44°)
C2/C3 1.93° (1.64°) 2.17° (1.78°) 1.85° (1.47°) 2.58° (2.35°)
C3/C4 1.53° (1.09°) 1.70° (1.38°) 2.29° (1.72°) 1.74° (1.55°)
C4/C5 1.91° (2.37°) 1.72° (1.51°) 1.89° (1.49°) 2.11° (1.58°)
C5/C6 1.59° (1.37°) 1.77° (1.32°) 2.35° (2.23°) 1.82° (1.35°)
C6/C7 1.79° (1.68°) 1.74° (1.34°) 1.76° (1.36°) 1.69° (1.29°)
Average 2.02° (2.21°) 2.05° (1.84°) 2.33° (2.20°) 2.15° (2.17°)
23
rehabilitation interventions last for several weeks. On group level, the repeatability
differences were almost zero, the result suggested that the cervical spine repeats its
motion accurately. However, the almost zero difference reflects that the data was
normally distributed. Thus, the absolute repeatability differences were extracted to
add this variance information to the motion repeatability.
A motor control with inherent variation and upright start position which also varies
as documented in study I may contribute towards an explanation for the large SD of
repeated motions reported in study II.
Biomechanically, cervical spine motion is commonly understood and modeled as a
‘spring-like’ structure (Haghpanahi, Haghpanahi, and Javadi 2012). Recently, many
studies suggest the cervical joint moves with variable speeds and directions (Anderst
et al. 2013b; Reinartz et al. 2009; Wang et al. 2017a; Wu et al. 2010). The complex
motion patterns demonstrated in this thesis with changing motion directions and
high variance of motion contributions between epochs do not support the ‘spring-
like’ models of joint movements. (Anderst et al. 2013b; Reinartz et al. 2009; Wang
et al. 2017a; Wu et al. 2010).
4.3 CLINICAL IMPLICATIONS
This is the first evidence to support the clinical assumption that flexion and
extension of healthy cervical joints are repeatable, and the repeatability is not
influenced by time delay. This result is important for clinical diagnosis and clinical
examinations, as the result to some extent confirms the previous practice. The results
support the assumption that healthy joint motions are repeatable. However, studies
of cervical joint motion in patients with neck disorders are necessary to assess
whether the variability in cervical joint motion patterns changes with neck pain.
The fluctuations and directions of cervical joint motion vary throughout flexion and
extension movements, which contrasts with most surgeons’ impression of cervical
joint motion that the joint motion increases or decreases constantly through cervical
flexion or extension. Thus, most surgeon’s clinical and scientific understanding of
repeated joint motions may not reflect the larger variance (SD) of results
demonstrated in this study.
4.4 SUMMARY
The average difference between repeated joint motions approached zero. This result
confirms the hypothesis that the cervical flexion and extension joint motions were
repeatable. However, the results also show a variance in absolute differences with an
average of approximately 2 degrees, this variance demonstrates a better motion
repeatability for groups compared to single subjects. The repeatability of the cervical
24
joint motion pattern may provide background for future clinical and scientific
investigations of the cervical motion pattern in different conditions.
25
5 QUANTIFICATION OF ANTI-DIRECTIONAL MOTION
5.1 ANTI-DIRECTIONAL MOTION
Anti-directional motion was defined as the motion opposite to the intended motion
direction (Fig 7). Previously, anti-directional motion has been documented as
reverse motion and inverse motion (Anderst et al. 2013c; Swartz, Floyd, and
Cendoma 2005). Swartz et al. reported that C6 through C7 exhibited a brief anti-
directional motion into extension during the neck flexion, followed by a brief anti-
directional motion of C0 through C2 (Swartz et al. 2005). Similarly, Craine et al.
concluded that the upper cervical segments of the lower cervical spine (C3-C7)
flexed during neck extension, and vice versa (Craine et al. 1993). However, the
distribution and quantity of the anti-directional motion during neck flexion or
extension is unknown.
Real-time imaging of dynamic neck motion was used to investigate cervical joint
motions (Anderst et al. 2013b; McDonald et al. 2010; Wu et al. 2010). Maximum
joint ROM was reported before full flexion or extension (Bogduk and Mercer 2000).
Anti-directional motion was observed during cervical spine flexion/extension
(Anderst et al. 2015; Craine et al. 1993; Reinartz et al. 2009). One study
demonstrated that some joints reached their maximum motions before the end-range
position, and these joints must move anti-directional to some extent from their
maximum ROM to reach the end-range position (Bogduk and Mercer 2000; Branney
and Breen 2014). Anti-directional motion has likewise been reported before
reaching full flexion and extension (Wu et al. 2010), and was found in
asymptomatic subjects (Abbott et al. 2006). Brief anti-directional motions of C6/C7
during flexion were accompanied by anti-directional upper cervical motions (C0-C2)
(Van Mameren et al. 1990). Anti-directional motions were also demonstrated for
C0/C1 and C7/T1 during cervical flexion and extension (Anderst et al. 2015).
26
Figure 7. Illustrations of anti-directional motion with two drawings of cervical
flexion and extension at the C5/C6 level. The figure shows C4 to C7 and the C5 is
marked with marking points 17, 18, 19 and 20 and C6 is marked with 21, 22, 23 and
24. The midplane of each vertebra was determined from the midpoints of the two
anterior and posterior points. The joint motion angle is calculated by subtraction of
two adjacent joint angles. Joint angle was the angle between two adjacent
midplanes. The joint motion changes in the drawings from p (left) to p+1 (right) of
the joint C5/C6 represent the joint motion during cervical flexion (top drawing) and
extension (bottom drawing). Anti-directional joint motion is defined as joint motion
opposite the intended motion direction. For neck flexion each instance of extension
27
joint motion is anti-directional joint motion for the specific joint, and vice versa for
neck extension.
5.2 JOINT MOTION DURING FLEXION AND EXTENSION
Cervical joint ROM has previously been investigated for individual joint ROM from
static upright and end-range positions (Auerbach et al. 2011; Takeshima et al. 2002;
Wu et al. 2010). However, static images of upright and end-range positions may not
reflect the dynamic neck motion of cervical joints ( Bible et al. 2010; Cobian et al.
2009).
The joint motion pattern of cervical flexion and extension is unclear; however, the
motion patterns were reported to show great variances (Study III). Anti-directional
motion is one component of dynamic cervical flexion and extension motions;
however, the proportion of pro-directional and anti-directional is unknown.
Both flexion and extension motion demonstrated approximately 40 degrees of
average anti-directional motion across joints (C0 to C7) (Study III). All joints
demonstrated anti-directional motion, and the anti-directional motion was scattered
throughout the dynamic cervical joint motions. The ratios between anti- and pro-
directional motion were 42.8 (9.7) % and 41.2 (8.2) % for flexion and extension,
respectively (Study III). Visual inspection of all joint motions showed that no joint
motions demonstrated continuously pro-directional or anti-directional motions.
During flexion, the upper cervical joints showed more anti-directional motions
compared with the lower cervical joints. As for extension the C1/C2 and C2/C3
indicated larger anti-directional motions compared with C0/C1, C3/C4, C4/C5 and
C5/C6 (Study III). Averaged anti- and pro-directional motions for each cervical joint
were presented in Table 5.
Table 5. Mean (SD) anti- and pro-directional motion and the ratio at each individual joint through
cervical flexion and extension movements
Joint Flexion Movement Extension Movement
Anti-direction Pro-direction Ratio Anti-direction Pro-direction Ratio
C0/C1 6.78 (4.24) 9.83 (5.18) 0.67 (0.28)¤† 4.02 (3.38) 15.24 (6.67) 0.29 (0.10)
C1/C2 9.32 (7.04) 15.44 (6.59) 0.55 (0.22) # 8.54 (4.51) 15.56 (4.62) 0.61 (0.20) &
C2/C3 7.81 (4.04) 13.10 (3.76) 0.60 (0.18) # 7.90 (4.18) 13.77 (3.57) 0.58 (0.20) &
C3/C4 4.25 (1.86) 10.99 (2.73) 0.43 (0.15) 5.42 (2.41) 12.94 (4.09) 0.39 (0.16)
C4/C5 3.85 (2.45) 12.78 (2.73) 0.33 (0.16) 4.46 (3.26) 14.58 (4.26) 0.28 (0.15)
C5/C6 3.11 (1.78) 14.85 (3.66) 0.22 (0.10) 4.73 (2.22) 13.67 (4.49) 0.35 (0.18) ‡
C6/C7 4.82 (3.06) 14.86 (4.29) 0.30 (0.13) 5.18 (3.03) 11.74 (3.94) 0.45 (0.20) ‡
Sum 39.94 (14.32) 91.86 (16.25) 0.43 (0.10) 40.24 (10.84) 97.50 (15.22) 0.41 (0.08)
28
Table 5. The anti- and pro-directional motion were presented in degrees. The ratios
between anti- and pro-directional motion for each joint were presented. ‘Sum’
indicates the anti-directional and pro-directional motion and ratios of all the
cervical joints from C0/C1 to C6/C7. For the flexion ratios C0/C1 was larger than
C3/C4, C4/C5, C5/C6 and C6/C7 (¤, P<0.001); C1/C2 and C2/C3 were larger
than C4/C5, C5/C6 and C6/C7 (#, P<0.02). For the extension ratios C1/C2 and
C2/C3 were larger than C0/C1, C3/C4, C4/C5 and C5/C6 (&, P<0.03). The C0/C1
ratio for flexion was larger than the extension ratio (†, P<0.002). In contrast the
C5/C6 and C6/C7 flexion ratio was smaller than the extension ratio (‡, P<0.05).
Figures 8 and 9 showed a representative sample of the diverse and irregular cervical
motion patterns found in study III. The patterns were non-linear with large
variations in pro- to anti-directional motions. The figures showed several joints with
maximum motion occurring before end-range of motion. Almost all subjects
demonstrated one or more joints where maximum ROM were reached before end-
range. This diversity in motion patterns was not possible without the scattered anti-
directional motion.
Figure 8. Neck flexion from one representative male subject. Pro- and anti-
directional motion directions interchanged with occasional larger one-directional
deviations. The maximum flexion C2/C3 motion was reached in the 6th epoch, and
the maximum motion was 4.05°. Maximum flexion motions of C2/C3, C3/C4, C4/C5
and C6/C7 were reached before the end-range. Thus, the joints of C2/C3, C3/C4,
C4/C5 and C6/C7 have to move anti-directionally before reaching end-range. The
motions were analyzed in 10% epochs as illustrated in the figure, and epochs with
29
signs (-) opposite the intended motion direction (+) demonstrated anti-directional
motion.
Figure 9. Neck extension from the subject in figure 8. Likewise, pro- and anti-
directional motion directions interchanged with larger one-directional deviations.
The maximum extension joint motion for C1/C2 and C5/C6 were reached before the
end-range, and it was also noted that C0/C1 moves predominantly anti-directionally
with maximum anti-directional motion in the 8th epoch. Anti-directional motion
occurred when the joint motion in an epoch changed in a direction opposite to the
intended motion direction.
Table 6 showed the average cervical joint ROMs across all subjects included in the
thesis. Cervical joint ROM is the change in angle of an individual joint between the
start position and the end position of the assessed motion. The table showed the
largest flexion contribution from C5/C6, and the largest extension contribution from
C0/C1 and C4/C5.
Table 6. Mean joint ROM (SD) in degrees of cervical flexion and extension
movements
Cervical Joint Flexion Movement Extension Movement
C0/C1 3.06 (4.39) 11.22 (8.37)
C1/C2 6.12 (6.27) 7.02 (5.50)
C2/C3 5.29 (3.80) 5.87 (4.77)
C3/C4 6.74 (3.43) 7.53 (5.00)
C4/C5 8.94 (4.21) 10.12 (5.06)
C5/C6 11.73 (5.23) 8.93 (5.51)
30
Table 6. Mean (SD) of cervical joint ROMs in degrees for all subjects included in
the thesis. Left column indicates cervical joints and SUM presents the average ROM
of the cervical spine. The middle column shows the joint ROMs between upright
posture and end-range flexion. The right column shows the joint ROMs between
upright position and extension. ROM indicates range of motion.
5.3 DISCUSSION
Study III investigated anti-directional motion of cervical joints after flexion and
extension movements. The study demonstrated approximately 40 degrees of anti-
directional motion for both flexion and extension movements. Sum of pro- and anti-
directional motion was demonstrated separately for each joint. The results confirmed
hypothesis 3 that all healthy cervical joints demonstrated anti-directional motions.
No individual joints showed continually increasing anti-directional or pro-
directional motion through cervical flexion or extension. The anti-directional motion
was intermittent and scattered through flexion and extension joint motion. The large
proportion of anti-directional motion contributed to the variations of joint motion in
the sagittal plane.
The cervical motion pattern of flexion and extension was subject-specific and
diverse. Data were normally distributed and therefore group results contrasted with
subject specific results. Group results were curvilinear and regular, and the group
results resample the common perception of joint motion as continuous and linear.
The method may influence image acquisition. Branney and Breen reported a
representative subject with the head and neck motion controlled by a pivot
mechanism (Branney and Breen 2014). This subject showed smaller amounts of
anti-directional motion in contrast to the free and unrestricted motions applied in this
study and in another study by Reinartz et al. (Reinartz et al. 2009). The analysis
method applied by Branney and Breen was semi-automated and included several
iterations which were averaged. The averaging may also have smoothened the joint
motion of the representative subject.
The ROMs of single cervical joints are proposed to provide more information on
cervical spine motion compared to neck ROM (Puglisi et al. 2004; Wu et al. 2010).
Joint ROM assessed from static flexion-extension radiographs or real-time videos
enhances the understanding of cervical spine kinematics.
C6/C7 10.04 (5.34) 6.57 (4.68)
SUM 51.92 (9.28) 57.19 (12.16)
31
A previous study supports that C5/C6 contributes most to cervical flexion (Kowalski
et al. 2005). The extension results are also in agreement with previous studies for
C4/C5 (Wu et al. 2010). However, the C0/C1 is different from previous studies as
these studies did not investigate the upper cervical joints (Anderst et al. 2013a;
Anderst et al. 2013b; Auerbach et al. 2011; Wu et al. 2010). Frobin et al. calculated
joint ROM from end-range flexion to end-range extension on radiographs for C0/C1
to C6/C7, where the largest motion occurred at C5/C6 in healthy males and C4/C5
in healthy females while the smallest motion at C2/C3 for both sexes (Frobin et al.
2002) (Table 6). With similar method Takeshima et al. documented the largest
motion at C5/C6 and the smallest motion at C2/C3 (Takeshima et al. 2002).
5.4 CLINICAL IMPLICATIONS
It is widely acknowledged that pro-directional cervical joint motion occurs during
cervical flexion and extension (Dvorak et al. 1992; Lind et al. 1989; Izzo et al.
2013). However, the anti-directional motion is commonly regarded as a rare healthy
occurrence. The concept of healthy anti-directional motion conflicts with the clinical
indication for potential biomechanical problems. The common clinical
interpretations of cervical palpation and of functional x-rays do not include a high
frequency of healthy cervical joints, which move intermittent anti-directionally. The
study also demonstrated healthy joints with very reduced motion or anti-directional
end range motion. This is in contrast to the common knowledge of joint motion
(Gregory, Hayek, and Mann-Hayek 1998; Tanaka, Irikoma, and Kokubo 2013),
where a joint moving anti-directionally or very little is an indication of a potential
problem (Leach and Pickar 2005; Chau and Griffith 2005). This study indicates that
new gold standards are necessary for the interpretation of cervical joint motions in
order to accommodate the large amount of healthy anti-directional motions (Wang et
al. 2017b).
5.5 SUMMARY
Healthy cervical joints move intermittent pro-directionally and anti-directionally
during flexion and extension movements. The cervical spine and head reach the end-
range of flexion or extension motion as a result of the combined anti- and pro-
directional motions. Anti-directional motion is scattered throughout cervical flexion
and extension motion. This study not only verifies the previous findings of anti-
directional reports also demonstrates phases with anti-directional motion. The
average flexion or extension joint motion contained approximately 40% of anti-
directional motion with respect to pro-directional motion. These results enhance the
understanding of cervical joint motion pattern in flexion and extension.
32
6 GENERAL DISCUSSION AND LIMITATIONS
This PhD work develops a novel method and technology to investigate cervical joint
motion. The thesis proposes a new understanding of cervical joint motion. The new
understanding improves the knowledge of joint motion by firstly clarifying the
distribution of repositioning errors in the upright position and secondly showing that
a similar variability to the upright position is maintained through the entire joint
motion. The thesis further adds to the explanation for the variability of cervical joint
motion by demonstrating a large proportion of anti-directional motion. The anti-
directional motion explains part of the variance of motion direction found during the
repetition study. Figure 10 gives a summary of the results and answers the questions
raised in Figure 1.
The average neck and joint ROM found in the studies is largely in agreement with
previous studies and the differences between studies can be explained by different
stratification of subjects and different methods (Dvorak et al. 1992; Hole, Cook, and
Bolton 1995; Hsieh and Yeung 1986; Reynolds et al. 2009; Salo et al. 2009;
Whitcroft et al. 2010; Williams et al. 2010; Youdas et al. 1992). Joint ROMs were
different between joints (C0/C1, C1/C2, C2/C3, C3/C4, C4//C5, C5/C6, C6/C7) and
between movement directions (Flexion, Extension). The largest motion
contributions came from C4/C5 and C5/C6 and these joints contributed three times
as much as C0/C1 during flexion. These results suggested that the size of the joint
contribution to a motion was not associated with size of the upright cervical joint
reposition errors, the repeatability between cervical motions or the proportion of
pro-directional respecting anti-directional motion.
Repositioning errors after flexion and extension movements were demonstrated for
each cervical joint, and the average group repositioning errors were small with larger
average absolute reposition errors of approximately 2.5 degrees. The results
demonstrated larger reposition errors in the upper cervical regions after flexion and
extension compared to the lower cervical regions.
The larger reposition error of healthy subjects in the upper cervical region may be a
confounder in a previous study. That study found also larger repositioning errors in
the upper cervical region in whiplash patients and attributed the larger reposition
error to traumatic whiplash (Treleaven 2011). This result may indicate that the larger
reposition errors found in the upper cervical joints may be attributed to the healthy
variation and not to whiplash.
The repeatability of cervical joint motion has been assumed both in the clinic and in
science; however, this assumption has never been tested. The thesis confirmed the
33
assumptions of repeatability with some limitations. The results demonstrated that
cervical joints repeat their flexion and extension motions with an average variation
of approximately 0.00 to 0.05 degrees in groups. The larger average variation of
approximately 2 degrees in the absolute data shows that the repeatability for single
joints was not as good as the group data. The small difference between group results
can be explained by the normal distribution of the data.
Part of the variations found in the repeatability study could be attributed to anti-
directional motions. The summed anti-directional motions across the cervical joints
during flexion or extension movements were approximately 40 degrees and 40% of
the pro-directional motions. Each individual cervical joint demonstrated scattered
anti-directional motion through flexion or extension joint motion similar to the
variation found in the repeatability study.
Previously, the anti-directional motion has only been identified (Anderst et al. 2015;
Craine et al. 1993; Reinartz et al. 2009); however, it has never been quantified. The
biomechanical mechanism underlying healthy anti-directional motion is unclear.
Small oscillation motion in a few degrees is suggested to be undershoot and
overshoot motions performed by the motor control system in order to follow a
predefined motor control strategy.
Larger deviations of anti-directional motion may be influenced by the factors which
also influence cervical ROM, such as sex, age, height, weight, anatomy, posture,
position sense, cervical proprioception, motor control and most importantly the
performed motion (Anderst et al. 2013b; Cho, Shin, and Kim 2014; Meisingset et al.
2016; Swartz et al. 2005; Wibault et al. 2013).
The thesis results challenge current spine surgeons’ impression of cervical spine
joint motion that conceptually joint motion is most often perceived as constantly
increasing or decreasing through extension or flexion. In contrast, the thesis
demonstrates great variability of cervical motion with intermittent pro-directional
and anti-directional motions.
There were several limitations in the PhD thesis. The image marking error is the
largest source of variation. Image distortion and magnification errors are well known
X-ray confounders. Out-of-plane motion may also influence the motion outputs; to
control this confounder, participants were asked to follow a vertical line to reduce
out-of-plane motions. Blinding of the investigator during marking was not possible,
as the procedures required marking of the initial image as a reference for subsequent
images.
Control over thoracic movement during acquisition could not be too restrictive as
the control may influence free and natural neck motion. Upright cervical spine
34
curvature (kyphosis, lordosis, normal curve) may also influence the cervical joint
motion pattern.
ROM for the neck and cervical joint have previously been assessed with different
methods. This thesis assessed neck and joint ROM for both sexes and from upright
position to full flexion or full extension, without further guidance as to what full
flexion or full extension was. Wu et al. applied similar fluoroscopy methods for
joint ROM between C2 to C7 (Wu et al. 2010).
The ROM of the neck depends on the performed motions. An example is flexion
with or without upper cervical retraction (localized forced upper cervical flexion)
(Walmsley et al. 1996). Pilot data shows that retraction increases the motion
contributions of the upper cervical joints. Likewise, other regional movements will
increase the motion contributions from that region and the joints within the region.
Stratification of healthy subjects into age, sex, height, weight and posture is likely to
influence the cervical joint contribution to the performed motions (Dvorak et al.
1992; Malmström et al. 2006). Methodological difference in data acquisition also
influences joint motion contribution to the examined neck motion. The motion
contributions are different between continuous motion from full flexion to full
extension or if the motions start from the upright position. The upright position
includes the variance of that position; however, motions initiated from that position
resemble the movement of daily living more than movement going from full flexion
to full extension.
Age and sex are factors which influence cervical ROM, and probably also the
individual joint motions within the ROM (Dvorak et al. 1992; Hwang and Jung 2015;
Smith, Hall, and Robinson 2008). The participants in the studies were of both sexes
between 20-30 years old and they do not represent all age groups.
Recurrence is a frequent feature of neck pain. Thus, the absence of neck pain within
the last three months may not be a guarantee that the participants are healthy and
without neck problems.
35
Join
t m
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on c
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acte
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Rep
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Stu
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tab
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Stu
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I
Anti
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36
Figure 10. The summary of the joint motion characteristics during sagittal cervical
flexion and extension movements in healthy subjects. Static repositioning ability was
assessed with real errors and absolute errors. The effect of time interval (long time
vs short time) on repositioning acuity between different tasks were examined as time
effects. Time effects on static and dynamic repositioning were investigated in Study I.
Study II investigated repeatability of dynamic motion. Study III investigated anti-
directional joint motion.
37
7 FUTURE PERSPECTIVES
Normative studies of healthy joint motion stratified according to age, sex and spinal
curvature are warranted. There is also a need for further exploration of healthy
subgroups and other characteristics of normal or healthy joint motion.
The findings of the thesis have only been demonstrated for healthy subjects, and
studies linking healthy results with pain conditions such as experimental muscle
pain, experimental ligament pain, whiplash, and chronic neck pain will be necessary
in future efforts.
Experimental muscle pain provides a method to study alteration in the cervical
motion pattern under similar pain conditions. The method would allow
investigations of the upright reposition error under short-term and similar pain
conditions. Likewise, experimental pain would also allow investigations of dynamic
cervical joint motions under similar pain conditions. The overall repositioning errors
of the cervical spine under experimental pain conditions are expected to be larger
compared with controls, and the variance in dynamic cervical motion is also
expected to increase (Breen and Breen 2017).
Neck proprioception and motor control strategy were altered by chronic neck pain
and whiplash (Misra and Coombes 2015; Treleaven 2011; Wibault et al. 2013).
Impairment of deep cervical muscles have been documented in chronic neck pain
and whiplash (Falla, Bilenkij, and Jull 2004; Johnston et al. 2008; Juul-Kristensen et
al. 2013; Peterson et al. 2016; Stapley et al. 2006). The deep cervical muscles are
the only muscles, which can control single cervical joint motions. The association
between pain, deep cervical motor control and anti-directional motion is an
interesting future research area.
38
8 CONCLUSION
This is the first dissertation, using a novel developed fluoroscopic video technology,
to demonstrate individual cervical joint repositioning ability, motion repeatability
and anti-directional motion during flexion and extension movements in healthy
adults. This thesis developed a novel fluoroscopy video technology to test the
repositioning ability of individual cervical joints after flexion and extension
movements. The technology can also examine the repeatability of the dynamic
motion and the anti-directional motion of individual joints. The healthy cervical
spine demonstrated that i) the averaged upright posture repositioning variation after
flexion and extension is approximately 2.5 degrees, ii) the upright reposition
variations in the upper cervical spine are larger compared to the lower cervical spine,
iii) the individual joint repeats its flexion and extension with an average variation in
real values ranging from 0.00º to 0.05º and in absolute values ranging from 2.02°to
2.33, iv) each individual cervical joint move pro-directionally and anti-directionally
through flexion and extension. Additionally, the healthy cervical spine shows
diverse increasing or decreasing joint motion pattern during flexion or extension.
Academically and clinically, the variation in the healthy cervical spine implies that i)
the larger repositioning variation in the upper cervical spine may not indicate
damage/injuries but healthy variations, and ii) the motion repeatability of the
cervical spine provides the background and baseline data for further clinical and
scientific investigation of cervical motion pattern, and iii) the results open the
possibilities of ways for better understanding cervical biomechanics. Generally, this
thesis concluded that the cervical spine, at the individual joint level, repeats its
fluctuated motion pattern with a number of variations.
39
9 ENGLISH SUMMARY
Pain in the neck region is one of the most common medical conditions. Neck pain is
a potential cause of altered neck proprioception and altered motor control. The
cervical spine is a multi-joint unit, and the cervical spine has been studied
extensively to assess the range of motion and repeated motions with associated
repositioning ability for persons without and with neck problems. However, the
repositioning ability and motion pattern of individual cervical joints have only been
described minimally until now.
Individual cervical joints’ upright posture repositioning ability (Study I), dynamic
motion repeatability (Study II) and anti-directional motion (Study III) were
examined in healthy subjects who were asked to flex and extend the cervical spine
from an upright posture to an end-range position.
Most cervical spine movements are initiated from the upright cervical posture or
postures closely related to this posture. Therefore, this posture is the baseline for the
studies. The distribution of reposition errors showed larger errors in the upper
cervical regions. The studies confirmed with some limitations the clinical and
scientific assumption that cervical joint motion was repeatable.
Individual cervical joint repositioning and movement are essential to understand
normal variations of the healthy cervical spine biomechanics. In the present work,
the repeatability of single joint flexion and extension movements, including
fluctuation of anti-directional joint motion (previously described as reverse motion
in clinical studies, converse motion in biomechanical studies) were examined.
To investigate the individual cervical joints’ repositioning ability, the subjects were
asked to return to the upright cervical posture as precisely as they could after a
cervical flexion or extension movement. A novel fluoroscopic video technology and
Matlab based program analyzed the individual joint repositioning errors from C0/C1
to C6/C7. The repositioning errors were presented as real errors and absolute errors
in degrees. Individual joint motion during flexion and extension was calculated in
degrees. For detailed joint motion pattern analysis, the flexion or extension
movement was evenly divided into ten epochs with respect to the C0/C7 ROM from
upright posture to end-range position. Repeated flexion and extension movements
were performed to examine the joint motion repeatability with long (1 week) and
short (20 s) time intervals. Anti- and pro-directional motions were measured to
reflect the variations during repeated joint flexion and extension.
The cervical spine returns to the upright cervical posture after flexion and extension,
as it counterbalances the multiple joint motions within the cervical spine. The
cervical joints returned after flexion and extension movements with positive or
40
negative joint repositioning errors. Despite the variations in the upright cervical
posture after cervical flexion and extension movements, the variations through
cervical flexion and extension movements were repeated with an error of
approximately 2.5 degrees.
Cervical joints move repeatedly through flexion and extension with an average
variation of 0.00º to 0.05º in real values, and an average variation of absolute values
ranging from 2.02°to 2.33°. The movements include anti-directional motion, which
contributes to the fluctuations of the flexion or extension of joint motions.
The average anti-directional motion of the healthy cervical spine was scattered
throughout flexion or extension movements. Moreover, the upper cervical joints
showed larger anti-directional motion compared to the lower cervical joints. The
current thesis confirms that the anti-directional motion exists in free and unrestricted
cervical flexion and extension movements with an approximately average of 40 %.
The results quantify the variations of cervical joint motion during flexion and
extension movements, which may help to understand interventions directed towards
improved joint motions. The variation of repositioning differences after flexion and
extension suggests that this variation should be considered, when head and neck
repositioning errors are applied in rehabilitation and in science.
41
10 DANSK SAMMENFATNING
Nakkesmerter er en af de mest almindelige sygdomme. Smerter kan være årsag til
ændret sensorisk og motorisk kontrol af nakken. Halshvirvelsøjlen er en
multifunktionsenhed, der er blevet undersøgt i vid udstrækning for at vurdere
hvirvelsøjlens bevægelser og repositioneringsevne hos personer med og uden
nakkesmerter. Imidlertid er halshvirvelsøjlens bevægelse og repositioneringsevne af
enkelte hvirvelled kun beskrevet i begrænset omfang indtil nu.
Studie I undersøger individuelle halshvirvelleds repositioneringsevne, studie II
undersøger reproducerbarheden af dynamiske halshvirvelleds bevægelser og studie
III kvantificerer anti-direktionelle bevægelser. I studierne blev raske forsøgspersoner
bedt om at bøje nakken forover og bagover fra den oprette stilling til fuld bevægelse
af nakken.
De fleste bevægelser af nakken begynder fra den opretstående stilling eller stillinger
tæt på denne kropsholdning. Derfor har nakkens oprette stilling været
udgangspunktet for indeværende undersøgelser. Nakkens øverste led returnerede til
udgangspositionen med større fejl end de nederste led. Undersøgelserne bekræftede
med nogle begrænsninger den kliniske og videnskabelige antagelse om, at
halshvirvelled gentager deres ledbevægelser.
Halshvirvelleds gentagene forover og bagover bevægelser hos raske blev undersøgt i
dette projekt. Evnen til at gentage bevægelser af halshvirvelled er vigtig for at forstå
normale variationer i nakkens biomekanik.
Forsøgspersonerne blev bedt om at returnere til den oprette stilling af
halshvirvelsøjlen, så præcist som de kunne efter forover og bagover bevægelsen. En
ny videoflouroskopisk teknologi har gjort det muligt at beregne de enkelte
ledbevægelser mellem C0/C1 og C6/C7. Repositionsfejlene efter forover og bagover
ledbevægelsen blev beregnet som reelle og absolutte fejl i grader. Forover og
bagover bevægelserne blev opdelt i ti intervaller af led bevægelsen mellem C0 til C7
for analyse af nakkens fulde led bevægelse. Gentagne forover og bagover
bevægelser blev udført for at undersøge reproducerbarheden af ledbevægelser med
20 sekunders og 1 uges mellemrum. Anti-direktionelle og pro-direktionelle
bevægelser blev målt for at vise variationerne under de gentagne bevægelser.
Halshvirvelsøjlen returnerer til den opretstående stilling efter forover eller bagover
bøjning med små repositionsfejl, idet større fejl af enkelte led kompenseres i andre
led. Repositioneringsfejl angives som positive eller negative. På trods af de
biologiske variationer i led bevægelsen returnerer halshvirvlsøjlen til den oprette
stilling efter forover eller bagover bøjning af nakken med en middelfejl på ca. 2.5
grader.
42
Halshvirvelled reproducerer forover og bagover bøjningsbevægelser med en
gennemsnitsvariation mellem 0.00º og 0.05º, og gennemsnitlige absolutte
bevægelser mellem 2.02°og 2.33°. Led bevægelserne indeholder anti-direktionelle
bevægelser (modsat rettede bevægelser), hvilket bidrager til variationerne i forover
eller bagover bevægelserne.
De anti-direktionelle bevægelser var fordelt igennem forover eller bagover
bevægelserne. De øverste halshvirvler viste mere anti-direktionel bevægelse end de
øvrige halshvirvler. Afhandlingen viser, at anti-direktionel bevægelse forekommer i
fri og ukontrollerede halshvirvelbevægelser med et gennemsnit på 40%.
Resultaterne kvantificerer de biologiske variationer af halshvirvelleds bevægelser
under forover og bagover bøjning. Resultaterne kan bidrage til at forstå og forbedre
behandlingen af nakkens biomekanik. Den biologiske variation af
repositionsforskelle efter forover og bagover bøjning peger på, at denne variation
bør overvejes, når repositionsfejl af hoved og nakke anvendes i rehabilitering og
forskning.
43
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Parnianpour. 2009. "Kinematic Analysis of Dynamic Lumbar Motion in
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52
12 AUTHOR’S CV
Xu Wang, born in 1986 in Xi’an, China, received the
master’s Degree of Clinical Medicine from a 7-Year direct
medical program in Jilin University, China in 2013 and the
Ph.D. degree in biomedical science from Aalborg University,
Denmark in 2018. During 2013-2018, he was supported by
China Scholarship Council (CSC) and S. C. Van fund to
study in Aalborg University. He is interested in spine motion
preservation and spine degeneration diseases.
Summary
ISSN (online): 2246-1302ISBN (online): 978-87-7210-231-3
Pain in the neck region is one of the most common medical conditions. Neck pain is a potential cause of altered neck proprioception and altered motor control. The cervical spine is a multi-joint unit, and the cervical spine has been studied extensively to assess the range of motion and repeated motions with as-sociated repositioning ability for persons without and with neck problems. However, the repositioning ability and motion pattern of individual cervical joints have only been described minimally until now. Individual cervical joints’ upright posture repositioning ability (Study I), dynamic motion repeata-bility (Study II) and anti-directional motion (Study III) were examined in healthy subjects who were asked to flex and extend the cervical spine from an upright posture to an end-range position. Most cervical spine movements are initiated from the upright cervical posture or postures close-ly related to this posture. Therefore, this posture is the baseline for the studies. The distribution of reposition errors showed larger errors in the upper cervical regions. The studies confirmed with some limitations the clinical and scientific assumption that cervical joint motion was repeatable. Individual cervical joint repositioning and movement are essential to understand normal variations of the healthy cervical spine biomechanics. In the present work, the repeatability of single joint flexion and extension movements, including fluctuation of anti-directional joint motion (previously described as reverse motion in clinical studies, converse motion in biomechanical studies) were examined. To investigate the individual cervical joints’ repositioning ability, the subjects were asked to return to the upright cervical posture as precisely as they could after a cervical flexion or extension move-ment. A novel fluoroscopic video technology and Matlab based program analyzed the individual joint repositioning errors from C0/C1 to C6/C7. The repositioning errors were presented as real errors and absolute errors in degrees. Individual joint motion during flexion and extension was calculated in degrees. For detailed joint motion pattern analysis, the flexion or extension movement was evenly divided into ten epochs with respect to the C0/C7 ROM from upright posture to end-range position. Repeated flexion and extension movements were performed to examine the joint motion repeatability with long (1 week) and short (20 s) time intervals. Anti- and pro-directional motions were measured to reflect the variations during repeated joint flexion and extension. The cervical spine returns to the upright cervical posture after flexion and extension, as it counter-balances the multiple joint motions within the cervical spine. The cervical joints returned after flexion and extension movements with positive or 40 negative joint repositioning errors. Despite the variations in the upright cervical posture after cervical flexion and extension movements, the variations through cervical flexion and extension movements were repeated with an error of approximately 2.5 degrees. Cervical joints move repeatedly through flexion and extension with an average variation of 0.00º to 0.05º in real values, and an average variation of absolute values ranging from 2.02°to 2.33°. The movements include anti-directional motion, which contributes to the fluctuations of the flexion or extension of joint motions. The average anti-directional motion of the healthy cervical spine was scattered throughout flexion or extension movements. Moreover, the upper cervical joints showed larger anti-directional motion compared to the lower cervical joints. The current thesis confirms that the anti-directional motion exists in free and unrestricted cervical flexion and extension movements with an approximately av-erage of 40 %. The results quantify the variations of cervical joint motion during flexion and extension movements, which may help to understand interventions directed towards improved joint motions. The variation of repositioning differences after flexion and extension suggests that this variation should be considered, when head and neck repositioning errors are applied in rehabilitation and in science.